JPH0214843A - Cutting of glass plate having scratch on half surface thereof - Google Patents

Abstract

In an apparatus for the breaking of glass sheets (2) scored on one side, especially provided with a metallic coating on one side, a breaking bar (7) or a rotationally driven breaking roller (28) that can be lifted from below against the glass sheet (2) are provided, and two abutments (9 and 10) acting from above against the glass sheet (2) are likewise included. The abutments (9 and 10) are not in physical contact with the topside of the glass sheet (2) but rather hold down the latter by an air cushion produced between these abutments and the topside of the glass sheet (2), this air cushion being formed by compressed air exiting from nozzles (14). In this way, friction movements that could damage the coating (3) of the glass sheet (2) during the breaking step are precluded.

Description

DETAILED DESCRIPTION OF THE INVENTION The invention provides a contact surface for a half-scratched glass pane, for example configured as a desk, which acts on the glass pane from above and is essentially parallel to the other. configured 1
A lever Ql that has a pair of supports and that can be contacted (anel (ekar)) from below between the supports.
The present invention relates to a device for cutting glass sheets with half-scratches, which has rolls that are optionally in rotational motion.

The above-mentioned device, which is also called a cutting table ([1rect+tish)], is a glass cutting machine.
A glass cutting machine is used to cut a glass plate with scratches on one side into a desired shape along the scratch line. The cutting process on the cutting table is then carried out by lifting a lever or a roll from its contact surface. And during the cutting process, the top surface of the glass plate and the sabot that presses the glass plate downward! Relative motion occurs between.

This movement can break the surface of the glass pane and, in particular, destroy the coating on it.

The risk of breaking the glass plate or damaging the coating on the glass plate is increased by the creation of fine glass fragments during the cutting process. The fragment then causes the glass sheet to break during the cutting process when it is intermediate between the support and the glass sheet.

The present invention addresses the problem of E & D, which is to describe an apparatus of the type mentioned at the outset, in particular with which a glass plate having a coating on one side can be cut without damaging the glass core, in particular its coating. It is the foundation.

This is achieved according to the invention by providing the support with an air outlet directed towards the glass pane, which outlet is connected to a gas medium under pressure, in particular gQ for air. .

In the cutting table of the invention, the support does not touch the support above the glass plate to be cut, but is pressed down by an air pillow between the support and the glass plate. In this way, destructive mutual movements between the support and the glass pane at the surface of the glass pane or the coating provided thereon are excluded.

Another advantage of the device according to the invention is that the support, unlike the support resting on the glass sheet, does not have to be precisely adjusted to the thickness of the glass sheet to be cut. In the case of a thick glass plate, it is the downward holding force exerted on the glass plate through the air pillow below the support of the present invention (
This is because if the distance is small, the distance will be large, and if the glass plate is thin (if the distance is large), the distance will be small. mosquito(
The small downward holding force required for cutting thin glass sheets is automatically provided without vertical adjustment of the support. Such downward holding force is increased when the glass sheet is thicker without adjustment of the support, thus producing a greater downward holding force, such as is necessary for cutting thick glass sheets. Thus glass sheets having a thickness of, for example, between 2 and 10 mm can be cut without direct adjustment of the support.

In a practical embodiment of the device according to the invention, the support is constructed hollow and has an air outlet on its side facing the glass plate, and the support has a gas outlet under pressure. and at least one source for a medium, in particular air.

The openings in the support are constructed either as round nozzles or as 7" I8-totes with crevice nozzles. In both cases there are a number of nozzles extending along the length of the WkeJl. In this way hand.

A particularly strong air pillow is formed between the support and the glass plate.

Even if the support is placed closely on the glass plate, the glass plate is still in the process of cutting? In order to avoid contact with the lower parts of the supports facing in opposite directions due to the action of levers or rolls, the contact surface or the lower surface of the support facing the glass plate is constructed obliquely. Various embodiments are excellent. The lower portion of the support adjacent to the lever or roll is then placed higher than the edges of the other lower portions. In this case, the lower surface of the support facing the contact surface or the glass plate is preferably constructed with a convex curved surface obliquely to the longitudinal direction.

Other details and features of the invention are apparent from the following description of embodiments with reference to the accompanying drawings.

FIG. 1 is a sectional view of a device for cutting a glass plate with half scratches.

FIG. 2 is a top view of a cutting table that is installed next to the non-scratched glass cutting table and has a static cutting point and a dynamic cutting point for the glass sheet. , is a detailed explanatory view of the cut portion of the glass plate in FIG. 2;

Only the essential parts are shown. A device for cutting glass panes filled with half-shaved tin has a contact surface 1, which is designed, for example, as a desk. The contact surface 1 is coated on the surface.

A glass plate 2 with, for example, a vapor-deposited metal coating jM3 is fed in the direction of the arrow 4. This glass plate 2 was provided with scratches 5 on its surface in cuts 1'' 6 on the contact surface 1.

It is moved in the direction of the arrow 5 until it is exactly on the lever 7. This lever 7 can move up and down in the direction of a two-way arrow 8.

Above the contact surface 1, supports 9 and 10 are provided on both sides of the lever 7, the mutual spacing of which can be varied in the directions of the two arrows. In this case, the supports 9 and 10 are mutually symmetrical with respect to the lever 7 even when the spacing between them is changed.

In order to perfectly accommodate glass sheets 2 of different thicknesses and possibly also to support the cutting process, the supports 9 and 10 can be raised and lowered relative to the contact surface 1 in the direction of the bidirectional arrow 12.

As shown in FIG. 1, support 9. and 10 are hollow, and the side facing the glass plate 2 (wall 1
3) has a large number of air exhausts [''14].

This air outlet opening 14 is constructed as a square nozzle in the illustrated embodiment and has three rows of round nozzles extending in the length direction of the supports 9 and 10.

A conduit for introducing gas under pressure, in particular air, is connected to the ends of the supports 9 and 10, and the introduced pressurized air flows out from the supports 9 and 10 through the nozzle 14. The glass plate 2 is pressed against the contact surface 1. When the iron tip 7 is raised, possibly together with the lowering of the supports 9 and 10, the glass plate 2 is broken along the scratches 5. There is no possibility that the supports 9 and 10 come into physical contact with the glass plate or the coating 3 thereon. As shown in FIG. 1, the lower surfaces 13 of the walls of the supports 9 and 10 are configured to be inclined relative to the contact surface 1. At that time, support 10 was IIglF, l edge 15.

The further edges 16 of the supports 9 and 10 are spaced apart. Moreover, the other lower surface of the wall 13 has a convex shape in the length direction of the sabots 1-9 and 10.

Supports 9 and 10 have a width of 10al, for example.

Depending on the size of the glass cutting machine, the length can be up to 3 m.

υ A cutting table is shown in FIG. 2, and is provided with a cutting point 21 for statically cutting the glass plate 2 having scratches 5 and a cutting point 22 for dynamically cutting. ing.

The hydrostatic cutting point 21 is implemented as shown in FIG. The glass plate obtained by cutting along the scratch 5 still has the scratch 23 and is fed in the direction of arrow 25 by a band 24 conveying perpendicularly to the contact surface 1 and then in the direction of arrow 27. In this direction, it is conveyed by means of a conveying band 2G towards a powered cutting point 22. This dynamic cutting point 22 has a static structure similar to that shown in FIG. 1, except that instead of the cutting trowel edge 7 it is provided with a roll 28 capable of rotating in the direction of the arrow 29. It corresponds to various cutting points. At this dynamic cutting point 22, the glass band coming from the static cutting point 21 scratches 23.
along which is cut during passage.

Static cutting of glass sheets 2 with scratches 4JA5 is primarily suitable for thick glass sheets or for glass sheets with a small spacing of the scratches 5 from each other, whereas dynamic cutting is primarily suitable for lateral cutting. Suitable for directional cutting (see FIG. 2 and accompanying explanation), particularly thin glass sheets or glass sheets with large mutual spacing of the scratches cannot be cut with dynamic cutting methods. It is noteworthy. In this case, the cutting roll 28, together with the supports 9 and 10, serves not only to deflect the glass sheet to be cut, but also to transport the glass sheet 2 through the powered cutting station 22. On the side of the support 1-9 of the cutting point 22 facing the other support, a nozzle 30 is additionally provided (FIG. 3).
. Gas, in particular air, flows out from there in a downward direction.

By this means, it is possible to prevent the force of the glass plate from lifting too much from the contact surface 1 and, depending on the circumstances, from colliding with the support 9. These nozzles are located particularly higher than the nozzles of the support 9.

The cutting table shown in FIG. 2 does not have to be constructed at an absolute angle; it can also be straight.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of a glass plate cutting device according to the present invention, and FIG. 2 is a top view of a cutting table having a part for statically cutting a glass plate and a part for dynamically cutting a glass plate. . 3 is a detailed explanatory diagram of the cut portion of the glass plate in FIG. 2. FIG. l Contact surface 2 Glass plate 4.11, 25, 27.29 Arrow 5.23 Shaved tin 6゛ Cut lower Lever heli 9, lO support 13 Lower surface of support (claim) 14
Air exhaust opening, round nozzle 20
Cutting table 21.22 Cutting point 24 Transport bunt 28 Lever roll 30 Side wall nozzle

Claims (1)

Claims: 1) The support (9, 10) is provided with an air outlet (14) directed toward the glass plate (2), and the air outlet (14) is under pressure. having a contact surface (1) for a scratched glass plate (2), for example configured as a desk, characterized in that it is connected to a supply source for a gaseous medium, in particular air; (2) having supports (9, 10) acting from above and oriented essentially parallel to each other and contacting the glass pane (2) from below in the middle of the wall to its abutment; A lever heli (7) that can be rotated, or a rotary drive roll (28) as the case may be.
Glass plate with scratches on half side (
2) the device for cutting 2) the supports (9, 10) are of hollow construction and have an air outlet (14) on the side facing the glass plate (2); , 10) in the support (9, 10) is connected to at least one supply source for a gaseous medium, in particular air, placed under pressure. Nozzle with a round opening (1
4) The device according to claim 1, characterized in that it is configured as 4) having a series of outlet openings (14) extending side by side along the length of the support (9, 10). 5) The device according to claim 1, characterized in that: 5) the outlet (14) for the gaseous medium is configured as a crevice nozzle or a through crevice nozzle; 6) the support (9); , 10) or a plurality of juxtaposed through-slit nozzles. 7) The contact surface (1), or the lower surface (13) of the supports (9, 10) facing the glass plate, is constructed in an inclined manner, in which case the lever (7) or the roll (28) 8) Contact device according to claim 1, characterized in that the edges (15) of the parallel supports (9, 10) occupy a higher position than the other edges (16) themselves. 8. The support according to claim 7, characterized in that the lower surface (13) of the support (9, 10) facing the surface (1) or the glass plate is constructed with an inclined convex curve in the direction of its length. Device 9) The spacing between the supports (9, 10) is such that the levers (7)
) or move (arrow 11) in contrast to the roll (28)
10) A device according to any one of claims 1 to 8, characterized in that it is provided with a lever (7) for carrying out a hydrostatic cutting process. 11) The device according to any one of claims 1 to 9, characterized in that a rotary-driven roll (28) is provided for carrying out the dynamic cutting process. 12) The second support (
13) The nozzle (30) of claim 11, characterized in that the nozzle (30) is directed towards the lever roll (28) on the top of the pry roll (28) and has a nozzle opening in the side wall directed towards the contact surface (1). The lower wall (13) of the support (9)
13. The device according to claim 12, characterized in that the device is spaced apart above the